Apparatuses and methods for holding, retaining, and/or processing glassware articles

ABSTRACT

According to embodiments disclosed herein, an apparatus may hold and retain glass articles during processing. The apparatus may define a plurality of receiving volumes for holding glass articles. The apparatus may include a bottom support floor, a glassware-securing member positioned above the bottom support floor, and a cover plate positioned above the glassware-securing member. The bottom support floor may include a plurality of fluid passages, the glassware-securing member may include a plurality of glassware-retaining openings, and the cover plate may include a plurality of fluid passages.

CROSS REFERENCE TO RELATED APPLICATIONS

The present application claims priority to U.S. Provisional ApplicationNo. 62/159,653 filed May 11, 2015 entitled, “Apparatuses and Methods forHolding, Retaining, and/or Processing Glassware Articles,” the entiretyof which is incorporated by reference herein.

BACKGROUND

1. Field

The present specification generally relates to magazine apparatuses forholding and retaining glass articles during processing and, morespecifically, to magazine apparatuses for holding and retaining glassarticles during ion-exchange processing.

2. Technical Background

Historically, glass has been used as a preferred material for manyapplications, including food and beverage packaging, pharmaceuticalpackaging, kitchen and laboratory glassware, and windows or otherarchitectural features, because of its hermeticity, optical clarity, andexcellent chemical durability relative to other materials.

However, use of glass for many applications is limited by the mechanicalperformance of the glass. In particular, glass breakage is a concern,particularly in the packaging of food, beverages, and pharmaceuticals.Breakage can be costly in the food, beverage, and pharmaceuticalpackaging industries because, for example, breakage within a fillingline may require that neighboring unbroken containers be discarded asthe containers may contain fragments from the broken container. Breakagemay also require that the filling line be slowed or stopped, loweringproduction yields. Further, non-catastrophic breakage (i.e., when theglass cracks but does not break) may cause the contents of the glasspackage or container to lose their sterility which, in turn, may resultin costly product recalls.

One root cause of glass breakage is the introduction of flaws in thesurface of the glass as the glass is processed and/or during subsequentfilling. These flaws may be introduced in the surface of the glass froma variety of sources including contact between adjacent pieces ofglassware and contact between the glassware and equipment, such ashandling and/or filling equipment. Regardless of the source, thepresence of these flaws may ultimately lead to glass breakage.

Additionally, ion-exchanged glass, sometimes referred to as chemicallystrengthened glass, may provide additional strength. However, both theexterior portion and the interior portion of a glass container must becontacted with an ion-exchange bath to balance the stresses imparted tothe glass. Suitably securing glass containers to allow for completesubmersion in an ion-exchange bath while not introducing flaws on thesurface of the glass is difficult.

Accordingly, a need exists for alternative apparatuses for holding glassarticles during processing to mitigate glass breakage while allowing forfull contact of the interior and exterior regions of glass articles withprocessing baths, such as ion-exchange baths.

SUMMARY

According to one embodiment, an apparatus may hold and retain glassarticles during processing. The apparatus may define a plurality ofreceiving volumes for holding glass articles. The apparatus may comprisea bottom support floor, a glassware-securing member positioned above thebottom support floor, and a cover plate positioned above theglassware-securing member. The bottom support floor may comprise aplurality of fluid passages, the glassware-securing member may comprisea plurality of glassware-retaining openings, and the cover plate maycomprise a plurality of fluid passages. Each of the bottom supportfloor, the glassware-securing member, and the cover plate may besubstantially planar. The bottom support floor, the glassware-securingmember, and the cover plate may be substantially parallel with oneanother. Each glassware-retaining opening of the glassware-securingmember may define a width dimension of the receiving volume. The bottomsupport floor and the cover plate may define a height dimension of thereceiving volume.

In another embodiment, an assembly may hold and retain glass articlesduring processing. The assembly may comprise a plurality of magazineapparatuses, and one or more of the magazine apparatuses may define aplurality of receiving volumes. One or more of the magazine apparatusesmay comprise a bottom support floor, a glassware-securing memberpositioned above the bottom support floor, and a cover plate positionedabove the glassware-securing member. The bottom support floor maycomprise a plurality of fluid passages, the glassware-securing membermay comprise a plurality of glassware-retaining openings, and the coverplate may comprise a plurality of fluid passages. Each of the bottomsupport floor, the glassware-securing member, and the cover plate may besubstantially planar. The bottom support floor, the glassware-securingmember, and the cover plate may be substantially parallel with oneanother. Each glassware-retaining opening of the glassware-securingmember may define a width dimension of the receiving volume. The bottomsupport floor and cover plate may define a height dimension of thereceiving volume.

In yet another embodiment, a method for ion-exchanging glass articlesmay comprise supplying an apparatus or assembly for holding andretaining glass articles during processing, positioning one or moreglass articles one or more of the receiving volumes of the apparatus orassembly, and at least partially submerging the apparatus or assembly inan ion-exchange bath to contact the one or more glass articles with theion-exchange bath.

Additional features and advantages of the apparatuses described hereinwill be set forth in the detailed description which follows, and in partwill be readily apparent to those skilled in the art from thatdescription or recognized by practicing the embodiments describedherein, including the detailed description which follows, the claims, aswell as the appended drawings.

It is to be understood that both the foregoing general description andthe following detailed description describe various embodiments and areintended to provide an overview or framework for understanding thenature and character of the claimed subject matter. The accompanyingdrawings are included to provide a further understanding of the variousembodiments, and are incorporated into and constitute a part of thisspecification. The drawings illustrate the various embodiments describedherein, and together with the description serve to explain theprinciples and operations of the claimed subject matter.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 schematically depicts a perspective view of a magazine apparatuswithout a cover plate, according to one or more embodiments shown anddescribed herein;

FIG. 2 schematically depicts a perspective view of a magazine apparatuswith a cover plate, according to one or more embodiments shown anddescribed herein;

FIG. 3 schematically depicts an exploded view of a magazine apparatus,according to one or more embodiments shown and described herein;

FIG. 4 schematically depicts a cross-sectional view of a glass article,according to one or more embodiments shown and described herein;

FIG. 5 schematically depicts an enlarged perspective view of a magazineapparatus without a cover plate, according to one or more embodimentsshown and described herein;

FIG. 6 schematically depicts the bottom support floor of FIG. 5,according to one or more embodiments shown and described herein;

FIG. 7 schematically depicts an enlarged perspective view of a magazineapparatus without a cover plate, according to one or more embodimentsshown and described herein;

FIG. 8 schematically depicts the bottom support floor of FIG. 7,according to one or more embodiments shown and described herein;

FIG. 9 schematically depict a cross-sectional view of a loaded cassetteassembly, according to one or more embodiments shown and describedherein;

FIG. 10 depicts a process flow diagram of a method for strengtheningglass articles by ion-exchange, according to one or more embodimentsshown and described herein;

FIG. 11 schematically depicts the process described in the flow diagramof FIG. 10, according to one or more embodiments shown and describedherein;

FIG. 12 schematically depicts a glass article at a non-normal angel,according to one or more embodiments shown and described herein;

FIG. 13 shows test data for vial filling, according to one or moreembodiments shown and described herein.

DETAILED DESCRIPTION

Reference will now be made in detail to embodiments of magazineapparatuses for holding and retaining glass articles during processing,examples of which are illustrated in the accompanying drawings. Wheneverpossible, the same reference numerals will be used throughout thedrawings to refer to the same or like parts. One embodiment of anapparatus for holding and retaining glass articles during processing isschematically depicted in FIG. 1. The magazine apparatus generallycomprises a plurality of receiving volumes, where each receiving volumecan hold and retain a glass article, such as a vial. The magazineapparatus may be suitable to securely hold the glass articles as theyare submerged in an ion-exchange salt bath. For example, in oneembodiment, glass articles may be secured in the magazine apparatus andthe magazine apparatus may be submerged in an ion-exchange bath in aprocess which chemically strengthens the glass articles. In someembodiments, several magazine apparatuses may be coupled with oneanother in an assembly, and the assembly may be submerged in theion-exchange bath. Generally, the magazine apparatuses may be suitableto be manipulated such that the glass articles may be submerged into theion-exchange bath at an angle non-normal relative to the surface of thebath.

The magazine apparatuses described herein may be suitable to hold andretain glass articles, such as glass containers with a wide variety ofgeometries. As used herein, “glass article” may refer to any glassware,such as, but not limited to glass formed in the shape of a vial,ampoule, ampul, bottle, flask, phial, beaker, bucket, carafe, vat,syringe body, cartridge or the like. Additionally, “glass articles” maybe referred to herein as “glassware” and these terms may beinterchangeable. Various embodiments of apparatuses for holding andretaining glass articles during processing will be described in furtherdetail herein with specific reference to the appended drawings.

As noted herein, the breakage of glass articles during processing and/orfilling is a source of product loss and may lead to processinefficiencies and increased costs. Additionally, cosmetic flaws inglass articles are often undesirable to users. Strengthening of glassarticles can assist in mitigating breakage and scratching. Glassarticles can be strengthened using a variety of techniques, includingchemical and thermal tempering. For example, chemical tempering,sometimes called ion-exchange strengthening, can be used to strengthenglass articles through the introduction of a layer of compressive stressin the surface of the glass articles. The compressive stress isintroduced by submerging the glass article in a molten salt bath,sometimes referred to as an ion-exchange bath. As ions from the glassare replaced by relatively larger ions from the molten salt, acompressive stress is induced in the surface of the glass. Duringchemical tempering, glass articles, such as glass containers, may bemechanically manipulated to both fill and empty the glass articles ofmolten salt.

While chemical tempering improves the strength of the glass articles,mechanical manipulation of the glass articles during the strengtheningprocess may introduce flaws in the surface of the glass. For example,contact between the glass articles and the fixturing, such as a magazineapparatus, used to retain the glass articles during processing, mayintroduce flaws in the glass, particularly when the glass articles andthe fixturing are initially submerged in the molten salt bath and/orwhen the fixturing and glass articles are withdrawn from the molten saltbath and rotated to empty the glass articles of molten salt.Specifically, as a glass article is submerged it may be buoyant and thusbe propelled upward relative to the fixturing. Moreover, after theion-exchange process is complete, the fixturing and glass articles arewithdrawn from the molten salt bath and the fixturing is rotated toempty the glass articles of molten salt contained within the interiorvolume of the glass articles. As the fixturing is rotated, the glassarticles may abruptly collide with the fixturing. This blunt forceimpact between the glass articles and the fixturing may introduce flawsin the surface of the glass.

In most cases the flaws are superficial and are contained within thelayer of surface compressive stress induced in the glass. This surfacecompressive stress prevents the flaws from growing into cracks. However,in some cases, the flaws may extend through the layer of surfacecompressive stress which may lead to breakage of the glass articles.

The magazine apparatuses for holding and retaining glass articles duringprocessing described herein mitigate the introduction of flaws in theglass articles retained therein. Additionally, the magazine apparatusesdescribed herein allow for acceptable levels of fluid contact by themolten salt bath with all areas (interior and exterior) of the glassarticle when the magazine apparatus is partially or fully submerged inthe molten salt bath. Referring now to FIGS. 1, 2 and 3, one embodimentof a magazine apparatus 100 for holding and retaining glass articles 900during processing is schematically depicted. The magazine apparatus 100generally includes a bottom support floor 500, a plurality ofglassware-securing members 200, and a cover plate 400. Specifically,FIG. 1 shows a magazine apparatus 100 which does not have an attachedcover plate 400, and FIG. 2 shows a magazine apparatus 100 with anattached cover plate 400. FIG. 3 shows an exploded view of the bottomsupport floor 500, the glassware-securing members 200, and the coverplate 400. When the magazine apparatus 100 does not have an attachedcover plate 400, glass articles 900 may be freely moved into and out ofthe magazine apparatus 100. However, when the cover plate 400 of themagazine apparatus 100 is positioned over the glassware-securing members200, glass articles 900 positioned in the magazine apparatus 100 areretained as the magazine apparatus 100 is manipulated and maneuvered,including when the magazine apparatus 100 is rotated about a horizontalaxis to facilitate emptying the glass articles 900 of a processingfluid. In other embodiments, the magazine apparatus 100 may not have anattached cover plate 400, and may instead utilize another section of anadjacently stacked magazine apparatus, such as the bottom support floorof a magazine apparatus stacked above the magazine apparatus 100, as itscover plate 400. It should be understood that, as used herein, a coverplate 400 may be a separate structure that is attached to the bottomsupport floor 500 and/or glassware-securing members 200 or may be aportion of another magazine apparatus 100.

In one embodiment, the components of the magazine apparatus 100 may beshaped and sized to securely hold glass articles 900 shaped as vials. Asshown in FIG. 4, the glass articles 900 may generally include a bodysection 902, a neck section 904 above the body section 902, and anopening 906 leading through the neck and connected to the interiorvolume 910. The body section 902 substantially surrounds the interiorvolume 910 of the glass articles 900 with a bottom section 914 and sidewalls 916. The neck section 904 generally connects the body section 902with the opening 906. The opening 906 may be surrounded by a collar 908extending outward from the top of the neck section 904 of the glassarticle 900. The body section 902 may have a curved bottom edge 918 anda curved area 912 adjacent the neck section 904. Generally, the necksection 904, body section 902, and collar 908 may have a generallycircular-shaped cross section, each comprising an exterior diameter. Inone embodiment, the diameter of the collar (d_(a) in FIG. 4) is greaterthan the diameter of the neck section (d_(n) in FIG. 4) and the diameterof the body section (d_(b) in FIG. 4) is greater than the diameter ofthe collar, d_(a). Additionally, the opening 906 comprises a diameter(d_(m) in FIG. 4), referred to sometimes herein as the diameter of themouth, which is less than the diameter of the neck (d_(n)). Each glassarticles 900 may have a major axis (in the Z-direction in FIG. 4) whichmay be normal to the diameter of the body d_(b) and the diameter of theopening d_(m).

Generally, the bottom support floor 500 may be substantially planar inshape, and the glass articles 900 rest upon the bottom support floor500. As shown in FIG. 3, the bottom support floor 500 is planar, and alength (i.e., the dimension in the X-direction) and width (i.e., thedimension in the Y-direction) of the bottom support floor are muchgreater than the height (i.e., in the Z-direction) of the bottom supportfloor 500. The bottom support floor 500 may comprise fluid passages 510to allow a processing fluid, such as the molten salt bath used inion-exchange processing, to pass through the bottom support floor 500and contact the glass articles 900 positioned in the magazine apparatus100. In embodiments, the bottom support floor 500 may be formed from arigid wire mesh, as depicted in FIGS. 1-3. In other embodiments, thebottom support floor 500 may comprise a planar sheet formed withmachined holes which a processing fluid, such as the molten salt bathused in ion-exchange processing, to pass through the bottom supportfloor 500 and contact the glass articles 900 positioned in the magazineapparatus 100. Alternatively, the bottom support floor 500 may beconstructed with any generally planar geometry and with openings whichallows for the passage of a fluid through the bottom support floor 500while simultaneously supporting a plurality of glass articles 900resting thereon. Generally, the bottom support floor 500 may be anygenerally planar shaped article which will allow for the passage offluid but does not allow for the passage of glass articles 900.

Positioned above the bottom support floor 500 are one or moreglassware-securing members 200. As used herein, he terms “above” or“below” generally refer to the relative positioning of components in theZ-direction of the coordinates depicted in FIGS. 1-3. Theglassware-securing members 200 may be substantially planar in shape, andcomprise a plurality of glassware-retaining openings 210. As shown inFIG. 3, the glassware-securing members 200 are substantially planar, anda length (i.e., in the dimension of the X-direction) and a width (i.e.,in the dimension of the Y-direction) of the glassware-securing member200 are much greater than the height (i.e., in the dimension of theZ-direction) of the glassware-securing member 200. While FIGS. 1-3depict embodiments of magazine apparatuses 100 comprising twoglassware-securing members 200, there can be any number ofglassware-securing members 200 positioned between the bottom supportfloor 500 and the cover plate 400, such as one, three, four, five, six,or even more glassware-securing members. Multiple glassware-securingmembers 200 may be positioned in a generally parallel configuration. Thenumber of glassware-securing members 200 may depend on the geometry ofthe glass articles 900 being retained.

Each glassware-securing member 200 comprises glassware-retainingopenings 210 which at least partially define a receiving volume 220 inwhich a single glass article 900 can be received and secured. In oneembodiment, the glassware-retaining openings 210 of theglassware-securing member 200 are approximately circularly shaped. Suchan embodiment may be suitable for housing glass articles with circularexterior cross sections, such as those depicted in FIG. 4. However, inother embodiments, the glassware-retaining openings 210 may havegeometries other than circular, such as triangular, rectangular,pentagonal, or other geometries suitable to securely house glassarticles 900 with cross-sectional geometries that are non-circular. Theglassware-retaining openings 210 may be slightly larger than the largestcross-sectional diameter of the glass articles 900 to be received andsecured therein, shown in the embodiment of FIG. 4 as d_(b).

The glassware-retaining openings 210 may be arranged in two dimensionalarrays in the X-direction and Y-direction. For example, theglassware-retaining openings 210 could be arranged in rows and columns,or could be arranged in other configurations such as the offset patternshown in FIG. 1.

In embodiments, a cover plate 400 may be positioned above the bottomsupport floor 500 and glassware-securing members 200. The cover plate400 may be substantially planar in shape and comprise a plurality offluid passages 410. As shown in FIG. 3, the cover plate 400 issubstantially planar, and a length (i.e., in the dimension of theX-direction) and width (i.e., in the dimension of the Y-direction) ofthe cover plate 400 is much greater than the height (i.e., in thedimension of the Z-direction) of the cover plate 400.

The cover plate 400 comprises fluid passages 410 which allow for aprocessing fluid, such as the molten salt bath used in ion-exchangeprocessing, to flow through the cover plate 400 and into the interiorregion of the magazine apparatus 100. In one embodiment, the fluidpassages 410 of the cover plate 400 are approximately circularly shaped.Such an embodiment may be suitable for housing glass articles 900 withcircular mouth cross sections, such as those depicted in FIG. 4.However, in other embodiments, the fluid passages 410 may havegeometries other than circular. The fluid passages 410 may be arrangedin two dimensional arrays in the X-direction and Y-direction. Forexample, the fluid passages 410 could be arranged in rows and columns,or could be arranged in other configurations.

The bottom support floor 500, the glassware-securing members 200, andthe cover plate 400 may be substantially parallel relative to oneanother. The bottom support floor 500, the glassware-retaining openings210 in the glassware-securing members 200, and the cover plate 400define a plurality of receiving volumes 220. Each receiving volume 220may securely house an individual glass article 900. The bottom supportfloor 500 and the cover plate 400 may define a height dimension of thereceiving volume 220 (in the Z-direction). The bottom support floor 500and the cover plate 400 secure a glass article 900 in the verticaldirection by restricting its movement in the vertical direction. Eachglassware-retaining opening 210 of the glassware-securing member 200defines a width dimension (in the X-direction and Y-direction of FIG. 1)of the receiving volume 220. As such, the glassware-retaining opening210 secures a glass article 900 by restricting its movement in the widthdirection (X-direction and Y-direction of FIG. 1). Generally, the glassarticle 900 is positioned in a receiving volume where it major axis isin the height dimension.

The magazine apparatus 100 may further comprise vertical supports 300that securely connect the bottom support floor 500, theglassware-securing members 200, and may removably secure the cover plate400. The vertical supports 300 can be any mechanical fastening devicesuitable to connect the bottom support floor 500, the glassware-securingmembers 200, and/or the cover plate 400 with one another. In someembodiments, all or at least a portion of the vertical support 300 maycomprise a unitary body. In one embodiment, one or more of the bottomsupport floor 500, the glassware-securing members 200, the cover plate400, and the vertical support 300 may be formed as a unitary body. Inother embodiments, one or more of the bottom support floor 500, theglassware-securing members 200, the cover plate 400, and the verticalsupport 300 may be secured together may mechanical means such as, butnot limited to, screws, bolts, welding, glued, etc. Note that FIG. 3does not depict vertical supports 300. In one embodiment, the verticalsupports 300 may allow for the cover plate 400 to be removably attachedto the other sections of the magazine apparatus 100.

FIGS. 5 and 7 depict embodiments of magazine apparatuses 100 (withoutcover plates) which have bottom support floors 500 with differinggeometries. FIG. 5 shows a magazine apparatus 100 that includes a bottomsupport floor 500 in a diagonal crisscrossing pattern (as depicted inFIG. 6). FIG. 7 shows a magazine apparatus 100 that includes a bottomsupport floor 500 comprising a wire mesh geometry. FIGS. 6 and 8 showthe bottom support floors 500 of the magazine apparatuses 100 depictedin FIGS. 5 and 7, respectively.

In one embodiment, one or more of the fluid passages 410 may be alignedwith the glassware-retaining openings 210. For example, each fluidpassage 410 may be positioned directly above a glassware-retainingopening 210, as is shown in FIGS. 1-3. The diameter of each fluidpassage 410 may be less than the diameter of each glassware-retainingopening 210. In one embodiment, the magazine apparatus 100 may bedesigned to house glass articles similar or identical in geometry to theglass article depicted in FIG. 4. The glassware-retaining openings 210may have a diameter slightly larger than the body (d_(b)) of the glassarticle 900. In some embodiments such as, but not limited to,embodiments where the fluid passages 410 are aligned with theglassware-retaining openings 210, the fluid passages 410 may be smallerthan the d_(b) of the glass articles 900. In one embodiment, thediameter of each fluid passage 410 above a glassware-retaining opening210 may be less than the diameter of each glassware-retaining opening210. Each fluid passage 410 may have a diameter that is larger than thediameter of the mouth d_(m) and less than the diameter of the collard_(a) of a housed glass article 900. In such a configuration, theopening 906 is not blocked by the cover plate 400 but the glass article900 in constrained in movement because its collar diameter d_(a) isgreater than the diameter of the fluid passage 410.

In another embodiment, a single fluid passage 410 may aligned and shapedto allow for fluid passage into several receiving volumes 220 defined byseveral glassware-retaining openings 210. For example, the fluidpassages 410 may be shaped as an elongated channels with ends shaped assemi-circles of the same diameter, and connecting the two semi-circleshaped ends are a channel having the width of the diameter of thesemi-circles. The diameter of the semi-circles may be equal to theranges described herein with reference to the circular shaped fluidpassages 410. Referring to FIG. 2, in such an embodiment, the portion ofthe cover plate 400 situated between adjacent circularly shaped fluidpassages 410 could be eliminated, forming elongated fluid passages 410.In embodiments, two, three, four, five, or even more circularly shapedfluid passages oriented in a line could be combined into an elongatedfluid passage 410 by eliminating the portion of the cover plate 400positioned therebetween.

In some embodiments, the bottom support floor 500 may be substantiallyidentical to the cover plate 400. In some of these embodiments, themagazine apparatus 100 may be stacked with another magazine apparatus100 so that the bottom support floor 500 of a top magazine apparatus 100serves as the cover plate 400 for a bottom magazine apparatus 100.

Without being bound by theory, it is believed that fluid passages 410that are aligned with glassware-retaining openings 210 allow forenhanced flow of fluids into and out of the glass articles 900, ascompared with some cover plate 400 geometries with more open area forfluid flow. One measure of the ability of the vial to fill is the Bondnumber (B_(o)), which is a measure of the relative significance ofbuoyant forces compared with surface tension at the meniscus/fluid-airinterface at the opening of the container. In order to drive filling ofthe vials with a processing fluid, such as molten salt, it may bedesirable to have a large Bond number where buoyancy forces (bubbleformation) dominate surface tension forces. In this case, the Bondnumber indicates a balance between surface tension and buoyant forces.The Bond number may be expressed as B_(o)=(ρgL²)/σ, where ρ=fluiddensity, g=acceleration due to gravity, L=characteristic length (radiusof opening), and σ=surface tension of fluid. From this formula, in manyembodiments, L is the most significant factor in whether a glass articlefills, since the ratio of density to surface tension may be nearlyconstant for molten salt over the typical range of ion exchangetemperatures. To this end it may be important to avoid any obstructionof the glass article mouth during filling.

One or more of the bottom support floor 500, the glassware-securingmembers 200, the vertical supports 300, the cover plate 400 may be madeof metal, such as stainless steel (e.g., 304L stainless steel). However,any material is suitable that can withstand the relatively hightemperatures of the molten salt bath. In one embodiment, one or morecomponents of the magazine apparatus 100 may be fabricated by laser orwater jetting of raw stainless steel sheet material into the desiredflat patterns and then forming and welding the sheets into their finalshape. The bottom support floor 500, the glassware-securing members 200,and/or the cover plate 400 may be electro-polished, which may deburr thesharp edges that may be created through the laser or water jettingprocess. Electro-polishing may also increase the surface finish whichaids in the draining or sheeting of liquids from the magazine apparatus100. In another embodiment, the bottom support floor 500, theglassware-securing members 200, and/or the cover plate 400 may bepassivated following the electro-polishing, which may further increasethe passive layer of the stainless steel to further increase thecorrosion resistance of the magazine apparatus 100.

In another embodiment, two or more magazine apparatuses 100 may bestacked adjacently and secured together in a cassette 608 to form anassembly 110, as shown in FIG. 9. In one embodiment, since two or moremagazine apparatuses 100 are in contact with one another, the bottomsupport floor 500 of a higher positioned magazine apparatus 100 canserve as the cover plate 400 for a magazine apparatus 100 positionedbelow. In such an embodiment, only one cover plate 400 per assembly 110may be included. In such an embodiment, the bottom support floor 500 mayhave fluid passages 510, such as those described in relation to thecover plate 400, and may be substantially identical to the cover plate400 of the uppermost magazine apparatus 100. For example, the bottomsupport floor 500 may comprise fluid passages 510 which have a diameterless than d_(a) and greater than d_(m) of a glass article 900. Inanother embodiment, the cover plate 400 may be integrated with thecassette 608, such that only the top magazine apparatus 100 loaded intothe cassette 608 includes a cover plate.

When vertical pressure is applied to the glass article 900, more stressmay be present in the curved bottom edge 918 and a curved area 912 thanthe side wall 916 of the body. In embodiments, a surface scratch orother informality on the curved bottom edge 918 and a curved area 912may be more likely to propagate into a crack which may undesirably causecomplete breakage of the glass article 900. In some embodiments,glassware-securing members 200 only contact the side wall 916 of theglass article 900, as shown in FIG. 9.

It should be understood that a cover plate 400, as used herein, mayinclude a bottom support floor of an adjacent apparatus. The cover plate400 may not be permanently fastened to the magazine apparatus 100, suchas to allow for removal of the glass articles 900. The cover plate 400may be fastened to the magazine apparatus 100 by any suitable mechanicalmeans, such as by fasteners, screws, bolts, or a geometry of the coverplate 400 and magazine apparatus 1000 designed to stably hold the coverplate 400 to the magazine apparatus 100.

Now referring collectively to FIGS. 1, 2, 10, and 11, the glass articles900 can be strengthened by ion-exchange while being held in thereceiving volumes 220 of magazine apparatuses 100. FIG. 10 contains aprocess flow diagram 501 of a method for strengthening glass articles900 by ion-exchange and FIG. 11 schematically depicts the processdescribed in the flow diagram. In a first step 502, glass tube stock1000 formed from an ion-exchangeable glass composition is initiallyshaped into glass articles 900 (specifically glass vials in theembodiment depicted) using conventional shaping and forming techniques.In step 504, the glass articles 900 are loaded into magazine apparatuses100 using a mechanical magazine loader 602. The magazine loader 602 maybe a mechanical gripping device, such as a caliper or the like, which iscapable of gripping multiple glass articles 900 at one time.Alternatively, the gripping device may utilize a vacuum system to gripthe glass articles 900. The magazine loader 602 may be coupled to arobotic arm or other, similar device capable of positioning the magazineloader 602 with respect to the glass articles 900 and the magazineapparatus 100. The magazine loader 603 positions individual glassarticles 900 in the receiving volumes 220.

In a next step 506, the magazine apparatus 100 loaded with glassarticles 900 is transferred with a mechanical conveyor, such as aconveyor belt 606, overhead crane or the like, to a cassette loadingarea. Thereafter, in step 508, a plurality of magazine apparatuses 100(one depicted) are loaded into a cassette 608. While only one magazineapparatus 100 is depicted in FIG. 11, it should be understood that thecassette 608 is constructed to hold a plurality of magazine apparatuses100, such as depicted in FIG. 9, such that a large number of glassarticles 900 can be processed simultaneously. Each magazine apparatus100 is positioned in the cassette 608 utilizing a cassette loader 610.The cassette loader 610 may be a mechanical gripping device, such as acaliper or the like, which is capable of gripping one or more magazineapparatuses 100 at a time. Alternatively, the gripping device mayutilize a vacuum system to grip the magazine apparatuses 100. Thecassette loader 610 may be coupled to a robotic arm or other, similardevice capable of positioning the cassette loader 610 with respect tothe cassette 608 and the magazine apparatuses 100.

In a next step 511, the cassette 608 containing the magazine apparatuses100 and glass articles 900 is transferred to an ion-exchange station andloaded into an ion-exchange tank 614 to facilitate chemicallystrengthening the glass articles 900. The cassette 608 is transferred tothe ion-exchange station with a cassette transfer device 612. Thecassette transfer device 612 may be a mechanical gripping device, suchas a caliper or the like, which is capable of gripping the cassette 608.Alternatively, the gripping device may utilize a vacuum system to gripthe cassette 608. The cassette transfer device 612 and attached cassette608 may be automatically conveyed from the cassette loading area to theion-exchange station with an overhead rail system, such as a gantrycrane or the like. Alternatively, the cassette transfer device 612 andattached cassette 608 may be conveyed from the cassette loading area tothe ion-exchange station with a robotic arm. In yet another embodiment,the cassette transfer device 612 and attached cassette 608 may beconveyed from the cassette loading area to the ion-exchange station witha conveyor and, thereafter, transferred from the conveyor to theion-exchange tank 614 with a robotic arm or an overhead crane.

Once the cassette transfer device 612 and attached cassette 608 are atthe ion-exchange station, the cassette 608 and the glass articles 900contained therein may optionally be preheated prior to submerging thecassette 608 and the glass articles 900 in the ion-exchange tank 614. Insome embodiments, the cassette 608 may be preheated to a temperaturegreater than room temperature and less than or equal to the temperatureof the molten salt bath in the ion-exchange tank 614. For example, theglass articles 900 may be preheated to a temperature from about 300°C.-500° C. However, it should be understood that the preheating step isoptional due to the relatively low thermal mass of the magazineapparatuses 100 described herein.

Without being bound by theory, thermal uniformity of the magazineapparatus 100 and glass articles 900 prior to introduction into theion-exchange tank may be important to maintaining temperature of thesalt bath in the tank. For example, introduction of room temperaturevials into hot salt may result in a solidification of salt around theopening of the glass article 900. Additionally, as the Bond numberformula suggests, the filling performance also correlates with the ratioof fluid density to surface tension, both of which are temperaturesensitive properties. This ratio decreases with temperature, which alsomay improve filling performance.

The ion-exchange tank 614 contains a bath of molten salt 616, such as amolten alkali salt, such as KNO₃, NaNO₃ and/or combinations thereof. Inone embodiment, the bath of molten salt is 100% molten KNO₃ which ismaintained at a temperature greater than or equal to about 350° C. andless than or equal to about 500° C. However, it should be understoodthat baths of molten alkali salt having various other compositionsand/or temperatures may also be used to facilitate ion-exchange of theglass articles. In some embodiments, the molten salt 616 should be heldat a temperature as high as is possible given process constraints.Without being bound by theory, it is believed that a higher salt bathtemperature may reduce the ratio of salt density to viscosity.

In step 512, the glass articles 900 are ion-exchange strengthened in theion-exchange tank 614. Specifically, the glass articles are submerged inthe molten salt and held there for a period of time sufficient toachieve the desired compressive stress and depth of layer in the glassarticles 900. As the glass articles 900 are submerged, the glassarticles initially have positive buoyancy as air escapes from theinterior volume of the glass articles and is replaced with molten salt.As the glass articles 900 rise due to the positive buoyancy, the glassarticles are vertically retained in position by the bottom support floor500, cover plate 400, and glassware-securing members 200.

In one embodiment, the glass articles 900 may be held in theion-exchange tank 614 for a time period sufficient to achieve a depth oflayer of up to about 100 μm with a compressive stress of at least about300 MPa or even 350 MPa. The holding period may be less than 30 hours oreven less than 20 hours. However it should be understood that the timeperiod with which the glass articles are held in the tank 614 may varydepending on the composition of the glass container, the composition ofthe bath of molten salt 616, the temperature of the bath of molten salt616, and the desired depth of layer and the desired compressive stress.

In one embodiment, the glass articles are dipped into the ion-exchangetank 614 while being held at a non-normal angle relative to the majoraxis of the glass article and the surface of the fluid in the tank(shown as a dashed line in FIG. 12). The non-normal angle is shown asangle 165 in FIG. 12. The orientation of the vial can also affect thereliability of the filling process. Without being bound by theory, it isbelieved that a vial that is introduced normal to the fluid surface ismore likely to form bubbles. This is caused by balancing the bubblebuoyancy to the hydrostatic pressure of the fluid. When the glassarticle 900 is titled, the forces are not aligned, allowing the bubbleto escape and the fluid to enter the glass article 900 more reliablywith less cavitation. The magazine apparatuses 100 and processesdescribed herein may allow a fixed, non-normal angle to be imparted onthe glass articles 900 with respect to the surface of the salt bathduring introduction into the salt bath. Furthermore, in someembodiments, glass articles 900 may be moved by buoyancy forces, andthese buoyancy forces may partially tip the glass article within theglassware-retaining openings 210 to achieve non-normal angles of theglass articles 900 with respect to the surface of the salt bath duringintroduction into the salt bath. Such motion caused by buoyancy forcesmay improve filling efficiency.

Additionally, the speed at which the glass article is submerged cancause changes in the reliability of the filling process. Generally,slower dipping speeds may more reliably fill the glass articles 900.However, it may be possible to utilize higher submersion speeds if theglass article 900 is submerged at a non-normal angle. Referring again toFIG. 12, in some embodiments, the speed of submersion may be increasedas angle 165 is decreased. In some embodiments, it may be desirable tosubmerge the glass article 900 where angle 165 is about 45°, such asfrom about 40° to about 50° or from about 35° to about 55°. In anotherembodiment, angle 165 may be about 0°, such that the opening of theglass article is substantially perpendicular to the surface of theion-exchange bath. For example, angle 165 may be from about −5° to about5° or from about −10° to about 10°.

After the glass articles 900 are ion-exchange strengthened, the cassette608 and glass articles 900 are removed from the ion-exchange tank 614using the cassette transfer device 612 in conjunction with a robotic armor overhead crane. During removal from the ion-exchange tank 614, thevarious fluid passages of the magazine apparatus 100 allow the moltensalt within the magazine apparatus to readily drain from each magazineapparatus 100. After the cassette 608 is removed from the ion-exchangetank 614, the cassette 608 and the glass articles 900 are suspended overthe ion-exchange tank 614 and the cassette 608 is rotated about ahorizontal axis such that any molten salt remaining in the glassarticles 900 is emptied back into the ion-exchange tank 614. As thecassette 608 is rotated, the glass articles 900 are maintained in itsposition in the ware receiving volume 125 by the ware keepers 120.Thereafter, the cassette 608 is rotated back to its initial position andthe glass articles are allowed to cool prior to being rinsed.

The cassette 608 and glass articles 900 are then transferred to a rinsestation with the cassette transfer device 612. This transfer may beperformed with a robotic arm or overhead crane, as described above, oralternatively, with an automatic conveyor such as a conveyor belt or thelike. In a next step 514, the cassette 608 and glass articles 900 arelowered into a rinse tank 618 containing a water bath 620 to remove anyexcess salt from the surfaces of the glass articles 900. The cassette608 and glass articles 900 may be lowered into the rinse tank 618 with arobotic arm, overhead crane or similar device which couples to thecassette transfer device 612. Similar to the salt bath submersion, theglass articles initially have a positive buoyancy upon being submergedin the rinse tank 618. As the glass articles 900 rise due to thepositive buoyancy, the glass articles are vertically retained inposition. The glass articles 900 may be dipped at a non-normal anglerelative to the surface of the salt bath, as discussed with regards todipping into the salt bath.

The cassette 608 and glass articles 900 are then withdrawn from therinse tank 618, suspended over the rinse tank 618, and the cassette 608is rotated about a horizontal axis such that any rinse water remainingin the glass articles 900 is emptied back into the rinse tank 618. Asthe cassette 608 is rotated, the glass articles 900 are maintained intheir position in the receiving volume 220. In some embodiments, therinsing operation may be performed multiple times before the cassette608 and glass articles 900 are moved to the next processing station.

In one particular embodiment, the cassette 608 and the glass articles900 are dipped in a water bath at least twice. For example, the cassette608 may be dipped in a first water bath and, subsequently, a second,different water bath to ensure that all residual alkali salts areremoved from the surface of the glass article. The water from the firstwater bath may be sent to waste water treatment or to an evaporator.

In a next step 516, the magazine apparatuses 100 are removed from thecassette 608 with the cassette loader 610. Thereafter, in step 518, theglass articles 900 are unloaded from the magazine apparatuses 100 withthe magazine loader 602 and transferred to a washing station. In step520, the glass articles are washed with a jet of de-ionized water 624emitted from a nozzle 622. The jet of de-ionized water 624 may be mixedwith compressed air.

Optionally, in step 521 (not depicted in FIG. 10), the glass articles900 are transferred to an inspection station where the glass articlesare inspected for flaws, debris, discoloration and the like.

While the magazine apparatuses have been shown and described hereinbeing used in conjunction with glass containers, such as glass vials, itshould be understood that the magazine apparatuses may be used to holdand retain various other types of glass articles including, withoutlimitation, Vacutainers®, cartridges, syringes, ampoules, bottles,flasks, phials, tubes, beakers, vials or the like, including bothround-form glass articles and non-round-form glass articles.

It should now be understood that the magazine apparatuses and methodsdescribed herein may be used to hold and retain glass articles duringprocessing. The magazine apparatuses restrict movement of the glassarticles while allowing for ion-exchange processing by contact withmolten salt baths.

It will be apparent to those skilled in the art that variousmodifications and variations can be made to the embodiments describedherein without departing from the spirit and scope of the claimedsubject matter. Thus it is intended that the specification cover themodifications and variations of the various embodiments described hereinprovided such modification and variations come within the scope of theappended claims and their equivalents.

EXAMPLES

The embodiments described herein will be further clarified by thefollowing examples.

Example 1

Different patterns of cover plates were examined for their impact onvial filling, including a diagonal crisscrossing geometry, sometimesreferred to herein as a “preform” geometry (as shown in FIG. 6), a wiremesh geometry (as shown in FIG. 8), and a machined plate with holesspecifically matched to each vial (the embodiment of FIGS. 2 and 3 wherethe hole is larger than the glass article opening). Table 1 showsresults of filling tests conducted with preform, wire mesh, and machinedhole geometries. For each test, 162 glass vials were submerged andevaluated for whether they filled with fluid.

TABLE 1 Test Number Cover Plate Geometry Fill % 1 Preform 90.1% 2 WireMesh 92.0% 3 Preform 71.0% 4 Wire Mesh 84.0% 5 Preform 68.5% 6 Wire Mesh79.6% 7 Preform 56.8% 8 Wire Mesh 95.1% 9 Preform 96.8% 10 Machinedholes 100.0% 11 Machined holes 99.3% 12 Machined holes 100.0% 13Machined holes 100.0% 14 Machined holes 100.0% 15 Machined holes 100.0%16 Machined holes 100.0%

The average fill rate for the preform geometry was 71.6%, 87.7% for thewire mesh geometry, and 99.9% for machined holes.

Example 2

Calculation were made to model glass vials dipped at varying immersionspeeds and at varying angles into a fluid. FIG. 13 depicts thecalculated vial filling time at varying immersion speeds and angles ofentry. Line 10 represents filling in 1 second, line 20 representsfilling in 2 seconds, line 30 represents filling in 3 seconds, and line40 represents filling in 4 seconds. The filling time is the time it tookto completely fill the vial (without the presence of bubbles). They-axis represents the immersion speed and the x-axis represents the vialangle, marked 165 in FIG. 12. As reflected in FIG. 13, higher immersionspeeds require greater angles relative to the processing fluid surface.

It will be apparent to those skilled in the art that variousmodifications and variations can be made to the embodiments describedherein without departing from the spirit and scope of the claimedsubject matter. Thus it is intended that the specification cover themodifications and variations of the various embodiments described hereinprovided such modification and variations come within the scope of theappended claims and their equivalents.

What is claimed is:
 1. An apparatus for holding and retaining glassarticles during processing, the apparatus defining a plurality ofreceiving volumes for holding glass articles and comprising: a bottomsupport floor comprising a plurality of fluid passages; aglassware-securing member positioned above the bottom support floor andcomprising a plurality of glassware-retaining openings; and a coverplate positioned above the glassware-securing member and comprising aplurality of fluid passages; wherein: each of the bottom support floor,the glassware-securing member, and the cover plate is substantiallyplanar; the bottom support floor, the glassware-securing member, and thecover plate are substantially parallel with one another; eachglassware-retaining opening of the glassware-securing member defines awidth dimension of the receiving volume; and the bottom support floorand the cover plate define a height dimension of the receiving volume.2. The apparatus of claim 1, further comprising vertical supports thatsecurely connect the bottom support floor, the glassware-securingmember, and the cover plate.
 3. The apparatus of claim 1, furthercomprising a second glassware-securing member positioned between thebottom support floor and the cover plate.
 4. The apparatus of claim 1,wherein the glassware-retaining openings of the glassware-securingmember are circularly shaped.
 5. The apparatus of claim 1, wherein oneor more of the fluid passages of the cover plate are aligned with aglassware-retaining opening.
 6. The apparatus of claim 1, wherein one ormore of the fluid passages of the cover plate are circularly shaped. 7.The apparatus of claim 1, wherein: one or more of the fluid passages ofthe cover plate are aligned with a glassware-retaining opening; one ormore of the fluid passages of the cover plate are circularly shaped; anda diameter of each fluid passage that is circularly shaped and alignedwith a glassware-retaining opening is less than a diameter ofglassware-retaining opening with which it is aligned.
 8. The apparatusof claim 1, wherein the cover plate and the bottom support floor aresubstantially identical.
 9. An assembly for holding and retaining glassarticles, the assembly comprising a plurality of magazine apparatuses,wherein one or more of the magazine apparatuses defines a plurality ofreceiving volumes and comprises: a bottom support floor comprising aplurality of fluid passages; a glassware-securing member positionedabove the bottom support floor and comprising a plurality ofglassware-retaining openings; and a cover plate positioned above theglassware-securing member and comprising a plurality of fluid passages;wherein: each of the bottom support floor, the glassware-securingmember, and the cover plate is substantially planar; the bottom supportfloor, the glassware-securing member, and the cover plate aresubstantially parallel with one another; each glassware-retainingopening of the glassware-securing member defines a width dimension ofthe receiving volume; and the bottom support floor and cover platedefine a height dimension of the receiving volume.
 10. The assembly ofclaim 9, wherein at least one of the magazine apparatuses do notcomprise a cover plate.
 11. The assembly of claim 9, wherein for atleast one magazine apparatus the height dimension of the receivingvolume is defined by the bottom support floor of a lower magazineapparatus and a bottom support floor of an upper magazine apparatus,wherein the upper magazine apparatus and the lower magazine apparatusare stacked on one another and are adjacent to one another.
 12. Theassembly of claim 9, where one or more of the magazine apparatusesfurther comprises vertical supports that securely connect the bottomsupport floor, the glassware-securing member, and the cover plate. 13.The assembly of claim 9, where one or more of the magazine apparatusesfurther comprises a second glassware-securing member positioned betweenthe bottom support floor and the cover plate.
 14. The assembly of claim9, wherein the glassware-retaining openings of the glassware-securingmember are circularly shaped.
 15. The assembly of claim 9, wherein oneor more of the fluid passages of the cover plate are aligned with aglassware-retaining opening.
 16. The assembly of claim 9, wherein one ormore of the fluid passages of the cover plate are circularly shaped. 17.The assembly of claim 9, wherein: one or more of the fluid passages ofthe cover plate are aligned with a glassware-retaining opening; one ormore of the fluid passages of the cover plate are circularly shaped; anda diameter of each fluid passage that is circularly shaped and alignedwith a glassware-retaining opening is less than a diameter ofglassware-retaining opening with which it is aligned.
 18. The assemblyof claim 9, wherein the cover plate and the bottom support floor aresubstantially identical.
 19. A method for ion-exchanging glass articlescomprising: supplying an apparatus for holding and retaining glassarticles during processing, the apparatus defining a plurality ofreceiving volumes for holding glass articles and comprising: a bottomsupport floor comprising a plurality of fluid passages; aglassware-securing member positioned above the bottom support floor andcomprising a plurality of glassware-retaining openings; and a coverplate positioned above the glassware-securing member and comprising aplurality of fluid passages; wherein: each of the bottom support floor,the glassware-securing member, and the cover plate is substantiallyplanar; the bottom support floor, the glassware-securing member, and thecover plate are substantially parallel with one another; eachglassware-retaining opening of the glassware-securing member defines awidth dimension of the receiving volume; and the bottom support floorand the cover plate define a height dimension of the receiving volume;positioning one or more glass articles in one or more of the receivingvolumes; at least partially submerging the apparatus in an ion-exchangebath to contact the one or more glass articles with the ion-exchangebath.
 20. The method of claim 19, wherein the glass article is submergedin the ion-exchange bath at a non-normal angle relative to the surfaceof the ion-exchange bath.